Abstract

Willow (<i>Salix</i>) is one of the most important ornamental tree species in landscape plants. One species, <i>Salix matsudana</i>, is widely used as a shade tree and border tree because of its soft branches and plump crown. Some varieties of <i>S. matsudana</i> were salt tolerant and could grow normally in coastal regions. However, the molecular mechanisms of salt tolerance for <i>S. matsudana</i> have been less clear. Here, we addressed this issue by performing a mapping experiment containing 195 intraspecific F₁ progeny of <i>S. matsudana</i>, derived from salt-sensitive 'yanjiang' and salt-tolerant '9901', grown by cuttings in a 100 mM NaCl solution. Growth performance of these progeny under salt stress was investigated, displaying marked genotypic variability with the coefficients of variance of 28.64-86.11% in shoot and root growth traits. We further mapped specific QTLs contributing to these differences to the <i>Salix</i> genome. Of the 204 QTLs identified, a few were detected to explain a remarkably larger portion of the phenotypic variation than many others. Many detected QTLs were found to reside in the region of candidate genes of known biological function. The discovery of growth QTLs expressed under salt stress provides important information for marker-assisted breeding of salt tolerant <i>Salix</i> varieties and founds the basis for the application of <i>S. matsudana</i> in coastal afforestation.